Abstract

The physical properties of cobalt oxide with varied oxidation states, and coordination numbers, in the transition series, have numerous applications. The present study explores the physical properties of BaCoO_2.6 nanoparticles synthesized through the sol-gel method. The X-ray diffraction figure exhibits a 25 nm crystallite size hexagonal phase. The observational data shows the reduction in the real part of impedance (), dielectric constant (), dielectric loss (), and a raise in ac conductivity of mixed type of conduction with an elevation in frequency analyzed through impedance spectroscopy. The conductivity due to grain and grain boundaries is shown foremost in the complex impedance analysis. The plot of (Seebeck coefficient) in the low-temperature range indicates p-type behavior and the metal-insulator transition in the as-synthesized sample. The sample characteristics suggest applications in optical and switching devices. The Seebeck coefficient is the generation of potential difference when subjected to temperature difference. Thermoelectric materials are associated with the concept of high electrical conductivity like crystals and low thermal conductivity to that of glass. Nanothermoelectric materials can decrease further the thermal conductivity through phonon scattering. Electrical characterization suggests the presence of both NTCR and PTCR behavior in the sample, and hence, it explores the application in thermistor/resistance temperature detector’s (RTD) and low dielectric constant and loss to electro-optical and higher conversion efficiency to storage devices. Additionally, impedance spectroscopy helps in the study of electrochemical systems and solid-state devices wherein the transition of metal-insulator is an add-on to the research.

1. Introduction

Strongly correlated electron systems consisting of insulators and electronic materials show uncommon, productive properties including colossal magnetoresistance, electromagnetic, spin-charge partition, transitions into metal-insulator, half-metallicity, and heavy fermion behavior and superconductivity. Cobalt in the transition metal oxides A_n+2Co_n+1O_2n+2 () adopt different oxidation states and probes its entry into electrochemistry and medical diagnostics. The overture studies of the BaCoO_3-δ system on powder samples revealed numerous hexagonal polytypes [1] that have not been discretely distinguished, accredited to BaCoO_3-δ (15H 3-δ <2.23, 12H (2.43<3-δ <2.49), 7H (2.52<3-δ <2.575), 2H-2.85<3-δ <3.0), and orthorhombic BaCoO_2.07 and BaCoO₂, while orthorhombic BaCoO_2.63 formed after annealing in O₂ had two other phases assigned to the cubic BaCoO_2.72 with a co-precipitate product non-indexed phase BaCoO_2.31 [2]. The specimen prepared by the sol-gel method is a low-temperature process involving the precursor solution inclusive of metal salts, a chelating agent (citric acid), and a diol (ethylene glycol). The advantages of the method are chemical composition with varied parameters of temperature, time, and atmosphere and are controllable to synchronize with the structural and morphological characteristics of the specimen. Eventhough there are disadvantages like sensitive to moisture and time-consuming process with several steps, the advantages such as low-cost, flexible synthetic route, easy to implement overshadows.

Though several methods have been adopted for the synthesis of BaCoO_3-δ using BaNO₃and CoNO₃(600°C-12 h, 900°C-10 h) and BaCO₃, Co₃O₄ precursors (≈1200 K-2 days) [3–6], this is the first study to synthesize nano powder BaCoO_2.6 using the sol-gel method with lesser annealing time and analyze its physicochemical properties that include Seebeck coefficient, ac and dc conductivity studies, dielectric properties, PTCR/NTCR behavior, and the metal-insulator transition.

2. Materials and Methods

2.1. Experimental Details

The nanocrystalline sample has been prepared by a citrate-nitrate gel method using varying compositions of starting materials, such as Ba (NO₃)₂, Co (NO₃).6H₂O, citric acid, and ethylene glycol, which were taken in a stoichiometric ratio of Ba₃Co₄O₉, dissolved in deionized water with pH 2 at 309 K, and placed on a hot plate with a magnetic stirrer at 80°C for 2 hours to form the gel, which was then transferred to a platinum crucible and kept in an electric furnace and heated at 700°C for 5 hours. At 310°C, auto-combustion lasting for a few seconds occurred [7, 8], and the ash product was manually ground and then pressed into pellets at 1 Gpa, sintered for 120 minutes at 900°C in the atmosphere, and left in the furnace for natural cooling [9] (precaution: due to the release of nitrogen oxides, heating has to be done in a closed chamber with adequate care).

2.2. Analysis of the Structure

2.2.1. X-Ray Diffraction (XRD) Method

The prepared sample was characterized by XRD with a Bruker-axs D8 diffractometer (40 KV, 30 mA) and DIFFRAC software, Bragg-Brentano reflection geometry, and treatment with CuKα (=1.05418 A). The data was collected between 10°C and 90°C in steps of 0.005 and at a scanning rate of 1/minute. The microstructural features and composition were studied using a scanning electron microscope (JOELJSM6390, Japan) having (EDAX) capability.

2.3. FTIR Analysis of the Synthesized Nanomaterial

Infrared spectra (FT-IR) from the sample were observed in the 400-4000 cm^-1via Fourier transform-infrared spectrometer (Perkin-Elmer spectrum).

2.4. Electrical Transport Measurements

Shaped rectangular bars of of the sample was used for the recording of Seebeck coefficient () and electrical resistance simultaneously (Seebsys, NorECS AS Norwegian Electro Ceramics) for the temperature of 30°C to 600°C in atmospheric air for a standard 4-probe technique with wide frequency range to evaluate dielectric constant as well as ac conductivity (Waynker multicomponent precision analyzer 6440B).

3. Result and Discussion

3.1. Structural Analysis

3.1.1. XRD of the BaCoO_2.6 Nanoparticle

Figure 1 displays the powder XRD of the Ba₃Co₄O₉ nanoparticle prepared by conventional sintering. The different crystalline phases present in the sample were confirmed by comparing the XRD pattern to reference phases of the Xpert high score plus software. Major peaks had been associated with the BaCoO_2.6, specified by its reflection planes (Figure 1), in concurrence with the preceding reports JCPDS01-071-2453) [6]. The compound BaCoO_2.6 becomes crystalline in the space group P63/m m c symmetry in the lattice parameter, and , and the unit cell volume . With the XRD data, the evaluation of the size of the crystallite was carried out by Scherrer equation, , where is the crystallite size (nm); is the full width at half maximum of the diffraction peak; is the shape factor (0.9); is the X-ray wavelength, and is the diffracting angle. The average crystallite size of the most intense peak (110) plane of BaCoO_2.6 was assessed and found to be approximately 25.26 nm. The crystallite size corresponds to the coherently diffracting domain size and not to the particle size. The peak with an asterisk () may correspond to Ba₃Co₄O₉ or BaCo₂O₄ (JCPDS23-110) secondary phase [8–10].

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Figure 1 

(a) Powder X-ray diffraction pattern (XRD) of the sample BaCoO_2.6 prepared by conventional sintering. (b) Main peaks of Figure 1(a) are highlighted.

The multiphase transitions of theBaCoO_2.6, over an extrinsic temperature range are shown in Figure 2. A selective list of efficient compounds certified as crystal structures is only specified completely in recent studies (BaCoO_2.6 → BaCoO₃ → Ba₃Co₂O₆ (CO₃)_0.6) from 973 K to 1173 K and is the successive phase transition sequence. Not much detectable phase of barium cobaltite was found in annealing temperatures of 623 K and 773 K. Comparing the plot’s e and f, we find that the diffraction peak of (e) is higher than the diffraction peak of (f), indicating that crystallization of (e) to be more than the crystallization of (f) [3, 11]. Hence, the start-up temperature for the synthesis of Ba₃Co₂O₆ (CO₃)_0.6 may be assumed to be 900°C for 2 h. The different characteristic properties of BaCoO₃ and Ba₃Co₂O₆ (CO₃)_0.6 will be analyzed in our future work.

Figure 2 

The multiphase transitions of the resultant product over an extrinsic temperature range.

3.2. Elemental Analysis of the Sample

The elemental analysis (EDAX, 1 KeV to 20 KeV) of the synthesized sample in Figure 3 shows the presence of expected elements. Figure 4 represents the SEM image with different magnification and the images reveal the grains in the range of 0.5 μm-5 μm.

Figure 3 

The elemental analysis (EDAX, 1 KeV to 20 KeV) of the synthesized sample.

Figure 4 

SEM image with different magnifications of BaCoO_2.6.

3.3. FTIR Analysis of the Sample

FT-IR analysis was carried out for detecting the presence of the functional groups and for analyzing the reaction mechanisms during the sol-gel process (Figure 5). The band specific to the NO₃^- is found at 1419.62 cm^-1, and the peak around 842 cm^-1 is associated with the distortion vibration of N-H bending mode. The absorption peak situated below 836 cm^-1 is due to barium-cobalt-oxygen stretching vibrations [12, 13]. The slight shoulder around 1636.51 cm^-1 denotes the asymmetrical stretched vibration of carboxylate anion and carbonyl groups [14]. The OH- group at 3407.68 cm^-1 and 2923.07 cm^-1 owes to the absorbed water during the sample preparation [15].

Figure 5 

FTIR spectrum of synthesized nanomaterial BaCoO_2.6.

3.4. Thermal Properties

The TGA/DTA spectrum for BaCoO_2.6 is illustrated in the Figure 6. The reduction in weight (≈0.3%) at T <150 C is mainly due to the loss of constituents such as water, solvents with low molecular weight, or gas desorption between 150°C and 250°C (≈1.9%), additives, or crystallization and first decomposition products. The total weight loss accounts for ≈2.2% at 300°C, and henceforth, no weight loss occurs indicating the completion of the combustion process and the formation of oxide phases.

Figure 6 

TG/DTA curve synthesized nanomaterial BaCoO_2.6.

3.5. Transport Properties

The Seebeck coefficient () is the ratio of the magnitude of the induced voltage to the temperature gradient across a material. It is caused by charge carriers diffusion and phonon drag. The () is very low for metals and much larger for semiconductors. The value of determined in the present study increases with temperature (≈40 μV/C) indicating a metallic phase from 35°C to 150°C, thereafter decreasing with increasing temperature in the insulating phase as shown in Figure 7(a). The rise and fall in the magnitude of () with temperature increase imply the predominance of both thermally accessible transport states and the carrier density [12–14]. To further characterize the temperature-dependent conductivity, the graph was plotted against the charge carrier transport properties, the reduction in activation energy, , and temperature. The slope of exemplifies the conduction mechanism as per Mott’s metal-to-insulator transition (MIT) model for disordered semiconductors (Figure 7(c)). The raise in electrical conductivity (positive slope) with an increase in temperature up to 325°C and thereafter decline (negative slope) with an increase in temperature may be attributed to PTCR/NTCR behavior, respectively, wherein the PTCR’s usage in current overload protection devices [15–17]. Figure 7(b) shows a transition at 325°C in conductivity of the sample, and this may be due to the casting back of charge carriers in the material. Transport properties like electrical conductivity and Seebeck coefficient may be enhanced through doping, and by increasing the density of the sample, the density of the sample remains 74% theoretical density [18].

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Figure 7 

(a) The Seebeck coefficient (). (b) Electrical conductivity. (c) of synthesized nanomaterial BaCoO_2.6.

3.6. Dielectric Properties

The enriched knowledge about dielectric analysis may shed light on the electrical properties of a material medium with varied temperatures and frequency. Dielectric constant () shown in Figure 8(a) initially decreases abruptly with the rise in frequency and is stable at higher frequency assuring that at the further side of a specific frequency of applied electric field, the exchange of electrons does not follow the alternating field. Therefore, polarization reduces resulting in a reduction in the dielectric constant () [19]. From Figure 8(b), it is observed that the constant low-frequency dielectric loss may be due to the blocking of charge carriers at the cathode resulting in the formation of space charge polarization, and the abrupt decrease at 100 kHz may be the sign of thermal activation and hopping of charge carriers on a lattice surface. Figure 8(b)-inset shows the loss tangent () curve wherein the resonating hopping frequency of electrons to the frequency of the applied electric field marks the peak indicating maximum electric energy being transmitted to the electrons and shooting up of loss at resonance [20]. Thus, the sample is more of energy storage with an extended lifetime and reduced charge-discharge time and less energy dissipater (Figure 8(c)) with applied frequency and temperature indicating high conversion efficiency [21, 22].

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Figure 8 

(a) Dielectric constant (). (b) Dielectric loss and inset: loss factor (). (c) Quality concerning variation in the frequency of synthesized nanomaterial BaCoO_2.6.

3.7. Ac Conductivity Studies

Figure 9(a) of ac conductivity figures the NTCR (negative coefficient of the temperature) behavior of the synthesized nanoproduct.

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Figure 9 

(a and b) Variation of ac conductivity concerning frequency and temperature.

Figure 9(b) denotes calculations of () and () ac conductivity and activation energy, respectively, of the sample using the relation and , where is the vacuum permittivity, is the Boltzmann constant, is the angular frequency, and σ₀ is the preexponential factor [23]. For most dielectric ceramics, conduction has a high value and also remains constant for all frequencies at higher temperatures (region III). In the region I, the ac conductivity () does not follow the conductivity relation and is considered a metallic behavior, also observed in the Seebeck measurement (Figure 7(a)). In the region II (mid-temperature region), the conductivity differs exponentially with the temperature that is no longer linear wherein the change in slope (from positive to negative) may be attributed to the facts such as a mixed type of conduction inducted by thermally activated charge carriers and the oxygen vacancies in the nanoproduct [24–27]. The presence of oxygen vacancies and transfer of charge carriers concerning metal-insulator connects the sample probe into the analysis of critical temperature of high-temperature superconducting cuprates, usage as catalysts for hydrogen evolution reaction in support of green energy, as the secondary power supply in integrated circuits, and current overload protection devices [28–30].

3.8. The Activation Energy of the Synthesized Nanomaterial

The activation energy () of the product evaluated from the slope of log σ_ac vs 1/T curve is listed in Table 1. It is clear that the lower mobility (i.e., low conductivity) with higher activation energies corresponds to the ionic conduction in region I. On the other hand, electronic conduction in the region II is connected to relatively highest mobility (i.e., high conductivity) as well as the lowest activation energy [31, 32]. The value in the region I and region II of the sample varies from 0.9 eV to 1.3 eV and 0.8 eV to 1.2 eV, respectively.

3.9. Impedance Analysis

This technique aids in separating the imaginary and real components of the complex impedance quantities to comprehend the structural property relationship of the sample. Figure 10(a) exhibits the difference in the real part of impedance () as a function of frequency at various temperatures. The data indicate a decrease in () in the low-frequency region followed by saturation in the high-frequency region (>100 kHz). The values of merging at higher frequencies suggest the discharge of space charge carriers [24]. The differences in the imaginary part of impedance () with frequency (i.e., loss spectrum) at various temperatures in Figure 10(b) reveal that peaks are found at temperatures >100°C. The distinct shift among peaks with a magnitude increase of for temperature suggests the contribution of immobile electrons. The position of the peaks shifting to the lower frequency on enhancing temperature and moderation in a peak width indicates the chances of the relaxation times distributed and the series capacitance presence [33, 34]. The occurrence of more polarization charge transfer processes can be inferred in the impedance plot through the presence of greater than one arc [26]. The frequency consistent with the maximum of correlates with the relaxation time with the expression: , where is the angular frequency [29]. Hence, the relaxation effect, as well as asymmetric peak broadening, is indicative of the non-Debye type of relaxation.

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Figure 10 

(a and b) and variation with frequency and inset: relaxation time.

Figure 10(b)-inset indicates the difference of relaxation time (inferred from loss spectrum) with an inverse of absolute temperature (10³/T) following the Arrhenius law given by , where is the Boltzmann constant, is the preexponential factor, and is the activation energy. The typical data confirms a temperature-dependent relaxation process with the distribution of relaxation time in 10⁻⁶ to 10⁻⁴ sec indicating an escalation in the process dynamics (i.e., charge/carrier transport) in the material due to elevation in temperature [35].

3.10. Nyquist Plot at Different Temperature

Nyquist plot points out the overall contribution percentage of bulk or grain boundary components which is accredited to the quality and electrical homogeneity of the material as for the bonding between the sintering/microstructure to the AC response. The plot also contributes to the magnitudes of the component resistances and capacitances and picturization of redox reactions occurring at the electrode cells [36]. Nyquist plot (vs.) at room temperature, 373 K and 423 K, with corresponding equivalent circuit is best fit obtained using electrochemical impedance analyzer (EIS) software (for 100 C as shown in Figures 11(a)–11(c) with the possibility of two semicircles, highlighting the presence of grain boundaries and grains within the sample. The observed increase in the size of semicircular arcs with an increase in temperatures is related to the increase of capacitance, indicating dielectric (capacitive) behavior of the sample (resulting in phase -90°C, Figure 12) in the sample [37]. As the size (height) of the semicircles observed in the impedance plot depends on the resistive responses of the components in the sample, it is hard to acknowledge the responses emerging from the grain and grain boundary relating to their high capacitance values [24, 38, 39].

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Figure 11 

(a–c) Nyquist plot at room temperature, 373 K and 423 K, and equivalent circuit of synthesized nanomaterial BaCoO_2.6.

Figure 12 

Variation of phase with frequency.

3.11. Modulus Studies

To identify the nature of relaxation behavior and to distinguish long-range conduction from short-range hopping motion, frequency dependence on the imaginary part of electric modulus is observed (Figure 13(a)). The value is low in the range of low frequency. Moreover, dispersion is seen with an increase in the frequency that can be corroborated by an insufficient restoring force regulating the movement of the charge carriers influenced by an induced electric field. The result affirms the exclusion of the electrode effect in the test sample [24]. In the plot of (f) shown in Figure 13(b), the peaks shift to a lower frequency side with the elevation in temperature, and the bit sharper peak exists at a low frequency (~460 Hz) at the highest temperature (150°C) indicating that the ions can travel over long distances, i.e., charge carriers can carry out hopping well between the sites. The high-frequency peaks corresponding to lower temperatures suggest the confinement of ions within their wells with localized motion. This behavior shows that the dielectric relaxation is an unusual thermally activated type wherein the hopping mechanism of charge carriers dominated intrinsically [38].

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Figure 13 

(a and b) Variation of and with the frequency of the synthesized nanomaterial BaCoO_2.6.

The power of synergistic use of both impedance and modulus spectroscopy vs. plot emphasizes the phenomenon of largest resistance. Contrastingly, vs picks up those of the smallest capacitance highlighting that the relaxation process is a short- or long-range motion of charge carriers. The impedance peaks () correspond to R/2 and the modulus peak to that of e₀/2C of that particular element [40]. Figure 14 shows the selective plot of impedance (), modulus () variation, and frequency due to different temperatures. The highest values coincide at a specific frequency in the synthesized BaCoO_2.6 indicating a similar time gap of impedance as well as modulus spectra, and also the matching of peaks at all temperatures suggests the long-range movement of charge carriers [41, 42]. Additionally, in the short-range peaks, and are observed in diverse frequencies, and long-range transmission of charge carrier peaks is seen at the same cycles.

Figure 14 

Combined plot of and of synthesized nanomaterial BaCoO_2.6.

The validation of the distribution of relaxation times with temperature dependence was done by plotting the in weighted coordinates, i.e., vs (-loss peak frequency) (Figure 15). A perfect overlapping of curve bands in a single master curve was not observed. The result conveys the conduction mechanism being altered with temperature exhibiting non-Debye type behavior and mixed conduction at high temperatures [39, 43].

Figure 15 

vs of synthesized nanomaterial BaCoO_2.6.

4. Conclusion

The synthesized BaCoO_2.6 powder using the sol-gel method was characterized by different techniques. The Seebeck coefficient () is positive, indicating p-type behavior and the graph confirms the metal-insulator transition in the material. The FTIR study confirmed the presence of functional groups, and the positive value of the Seebeck coefficient () indicates p-type behavior. The electrical studies suggest both NTCR and PTCR behavior in the sample and its applications in thermistor/RTD. The characteristics of low dielectric constant, dielectric loss, and low dissipation factor with high frequency indicate enhanced optical quality and higher conversion efficiency, hence the sample’s research in electro-optical and storage devices with less charge-discharge time. The characteristic reduction in low dielectric constant and high-frequency dielectric loss concludes the enhanced optical quality and low dissipation factor to energy storage/capacitors, and the features of MI transition suggest the sample probe into electrical and optical switching devices and secondary power supply in integrated devices. The electrical studies suggest both NTCR and PTCR behavior in the sample and its applications in thermistor/RTDs. The impedance studies of the sample affirm the existence of grain in bulk as well as the grain boundary effects. The complex impedance spectroscopy study suggests the long-term mobility of charge carriers as well as non-Debye type with mixed conduction in the material. More studies are required to shower an insight into deducing further information and discern for a better interpretation of the results obtained.

Data Availability

All data generated or analyzed during this study are included in the published article.

Conflicts of Interest

There exists no conflict of interests.

Acknowledgments

The author (Fareenpoornima Rafiq) is grateful to ARCI lab, Chennai, for having extended the facilities for X-ray diffraction studies and electrical conductivity and Seebeck coefficient measurements, to Karunya University for SEM/EDX measurements, and to the Department of Physics, Loyola College, Chennai, for dielectric studies.